Download Neuraxial Blockade Anatomy and Landmarks

NEURAXIAL BLOKADE
Dr: Ahmed Thallaj
Associate Professor, college of medicine, KSU
Head of regional Anesthesia division
Objectives
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Relevant anatomy and surface landmark for
Neuraxial block.
Differences between spinal and epidural.
Equipment and local anesthetics.
Indication and contraindication.
Side effects, complications and treatment.
LAST
Knowledge of anatomy for neuraxial
blockade is essential!
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7 cervical vertebrae
12 thoracic vertebrae
5 lumbar vertebrae
Sacrum
Coccyx
Cervical
Vertebrae
Thoracic
Vertebrae
Lumbar
Vertebrae
Individual Vertebral Anatomy
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Each vertebra consists of a pedicle, transverse
process, superior and inferior articular processes, and
a spinous process.
Each vertebra is connected to the next by
intervertebral disks.
There are 2 superior and inferior articular processes
(synovial joints) on each vertebra that allows for
articulation.
Pedicles contain a notch superiorly and inferiorly to
allow the spinal nerve root to exit the vertebral
column.
Vertebral Anatomy- Top View
Transverse
Process
Spinal Canal
Vertebral
Body
Spinous
Process
Lamina
Intervertebral Disc
Spinal Nerve
Root
Intervertebral
Foramina
Thoracic
Vertebrae
Lumbar
Vertebrae
Angle of transverse process
will affect how the needle is
orientated for epidural
anesthesia or analgesia.
With flexion the spinous
process in the lumbar region is
almost horizontal. In the
thoracic region the spinous
process is angled in a slight
caudad angle.
Lumbar Extension versus Flexion
L2
L5
Interlaminar spaces are larger in the lower lumbar region. If an
anesthesia provider finds it challenging at one level it is important to
remember that moving down one space may provide a larger space.
Ligaments that support the vertebral column
Ventral side:
Anterior and
posterior
longitudinal
ligaments
Dorsal
side:
Important
since these
are the
structures
your needle
will pass
through!
Ligaments are identified by tactile
sensation (feel)
Dorsal ligaments transversed
during neuraxial blockade.
With experience the
anesthesia provider will be
able to identify anatomical
structures by “feel”.
Termination of Spinal Cord
In adults usually ends at L1.
Infants L3
There are anatomical
variations. For most adults
it is generally safe to place a
spinal needle below L2.
Surface Anatomy and Landmarks
Locating prominent cervical and thoracic
vertebrae
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C2 is the first palpable vertebrae
C7 is the most prominent cervical vertebrae
With the patients arms at the side the tip of the
scapula generally corresponds with T7
Palpation of Spinous Process
Spinous Processes
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Generally are palpable to help identify the midline
If unable to palpate the spinous process one can
look at the upper crease of the buttocks and line up
the midline as long as there is no scoliosis or other
deformities of the spine
What is Tuffier’s Line?
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A line drawn between the highest points of both
iliac crests will yield either the body of L4 or the L4L5 interspace.
Anatomical Considerations of the Spinal
Cord and Neuraxial Blockade.
The Subarachnoid Space is a continuous
space that contains
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CSF
Spinal cord & nerves
CSF
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Clear fluid that fills the subarachnoid space
Total volume in adults is ~100-150 ml (2 ml/kg)
Volume found in the subarachnoid space is ~35-45
ml
Continually produced at a rate of 450 ml per 24
hour period replacing itself 3-4 times
CSF
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Reabsorbed into the blood stream by arachnoid villi.
Specific gravity is between 1.003-1.007 (this will
play a crucial role in the baracity of local anesthetic
that one chooses)
CSF plays a role the patient to patient variability in
relation to block height and sensory/motor regression
(80% of the patient to patient variability)
Body wt is the only measurement that coincides with
CSF volume (this becomes important in the obese and
pregnant).
Membranes that surround the spinal cord
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Pia mater- highly vascular, covers the spinal cord and
brain, attaches to the periosteum of the coccyx ( Filum
terminalis)
Arachnoid mater- non vascular and attached to the
dura mater. Principal barrier to the migration of
medications in and out of the CSF.
Dura mater (“tough mother”)- extension of the cranial
dura mater, extends from the foramen magnum to S2.
Filum Terminale
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An extension of the pia mater that attaches to the
periosteum of the coccyx.
Epidural Space Anatomy
Epidural Space Anatomy
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Extends from the formen magnum to the sacral
hiatus
Epidural Space Anatomy
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The epidural space surrounds the dura mater
anteriorly, laterally, and most importantly to us
posteriorly.
The Bounds of the Epidural Space are as
follows:
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Anterior- posterior longitudinal ligament
Lateral- pedicles and intervertebral ligaments
Posterior- ligamentum flavum
Ligamentum Flavum
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Posterior to the epidural space
Extends from the foramen magnum to the sacral
hiatus
Distance from skin to ligament varies from 3-8 cm in
the lumbar area. It is 4 cm in 50% of the patients
and 4-6 cm in 80% of the patients.
Thickness of the ligamentum flavum also varies. In
the thoracic area it can range from 3-5 mm and in
the lumbar it can range from 5-6 mm
Contents of the Epidural Space
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Fat
Areolar tissue
Lymphatics
Blood vessels including the Batson venous plexus
Definition
Spinal anesthesia :
Injection of small amounts ( 2-3 ml) of local anaesthetics into
the CSF at the level below ( L2 ) ,where the spinal cord
ends, anesthesia of the lower body part below the
umbilicus is achieved.
Indication
Operations below the umbilicus: hernia repairs,
gynaecological, urological operation, orthopedics,
Any operation on the perineum or genitalia.
Spinal Anesthesia
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Contraindications
 Absolute:
 Refusal
 Infection
 Coagulopathy
& anticoagulated patient
 Severe hypovolemia
 Increased intracranial pressure
 Severe aortic or mitral stenosis
 Relative:
 Use
your best judgment
Sterility
Sitting Vs. Lateral decobitus
Spinal Technique
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Midline Approach
 Skin
 Subcutaneous
tissue
 Supraspinous ligament
 Interspinous ligament
 Ligamentum flavum
 Epidural space
 Dura mater
 Arachnoid mater
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Paramedian or Lateral Approach
 Same
as midline excluding supraspinous &
interspinous ligaments
Spinal needles type
PDPH
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Develop 12-48 hours after spinal
anesthesia.
Headache improve when lying supine.
PDPH; Treatment
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Conservative.
Epidural blood patch.
Spinal anesthesia; single shot technique
Baricity( a concern only in spinal
anesthesia)
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Hyperbaric
Typically prepared by mixing local with dextrose
 Flow is to most dependent area due to gravity
 Very predictable spread
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Hypobaric
Prepared by mixing local with sterile water
 Flow is to highest part of CSF column
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Isobaric
Neutral flow that can be manipulated by positioning
 Increased dose has more effect on duration than
dermatomal spread
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Note: Be cognizant of high & low regions of spinal
column
Hyperbaric bupivacaine is prepared
by mixing it with dextrose
Sterile, clear
Preservative free
3 ml ampoules
See the expiry date
Be sure it is bupivacaine??
Sympathetic, Sensory & Motor
Blockade
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Spinal Injection
 Sympathetic
block is 2 dermatomes higher than sensory
block
 Motor block is 2 dermatomes lower than sensory block
 Detect the sensory level by cold sensation test,
( Ice cubes).
Block order B> C=A delta> A beta>A alfa
Dermatomes of the Body
Spinal Anesthesia Levels
Spinal Anesthesia
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Complications
 Failed
block
 Back pain (most common)
 Spinal head ache
 More
common in women ages 13-40
 Larger needle size increase severity
 Onset typically occurs first or second day post-op
 Treatment:
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Bed rest
Fluids
Caffeine
Blood patch
Spinal Anesthesia
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Complications
 Epidural
hematoma
 Epidural abscess
 Meningitis
 Cauda equina
 Neurological deficit
 TNS
 Bradycardia--- Cardiac arrest
Hypotension
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Treatment
 Best
way to treat is physiologic not pharmacologic
 Primary Treatment
 Increase
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the cardiac preload
Large IV fluid bolus within 30 minutes prior to spinal placement,
minimum 1 liter of crystalloids
 Secondary
Treatment
 Pharmacologic
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Ephedrine
EPIDURAL ANESTHESIA
EPIDURAL ANESTHESIA
Epidural anesthesia; catheter technique
Isobaric bupivacaine (20 ml)
Slow onset (30 min), less dense block
Touhy needle
Loss of resistance technique
Catheter technique
Epidural Test dose
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After checking the catheter
Careful aspiration, NO blood or CSF
3 ml Lidocaine 1.5% mixed with epinephrine 5
micg/ml
With careful monitoring, give the epidural
injection15-20 ml bupivacaine in allequete.
Local anesthetics
Mechanism of Action
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Un-ionized local
anesthetic defuses into
nerve axon & the
ionized form binds the
receptors of the Na
channel in the
inactivated state
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Duration of Action
 The
degree of protein binding is the most important
factor
 Lipid solubility is the second leading determining factor
 Greater protein bound + increase lipid solubility =
longer duration of action
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Toxicity & Allergies
 Esters:
Increase risk for allergic reaction due to paraaminobenzoic acid produced through ester-hydralysis
 Amides:
Greater risk of plasma toxicity due to slower
metabolism in liver
LAST
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Exceeding the maximum save dose( Bupivacaine
2mg/kg), Lidocaine (5mg/kg)
Intravascular injection
LAST(CNS)
LAST (CVS)
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Tachycardia & Hypertension
Hypotension
Wide QRS
VF
Cardiac arrest
LAST; Management
References
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Brown, D.L. (2005). Spinal, epidural, and caudal anesthesia. In R.D. Miller
Miller’s Anesthesia, 6th edition. Philadelphia: Elsevier Churchill Livingstone.
Burkard J, Lee Olson R., Vacchiano CA. (2005) Regional Anesthesia. In JJ
Nagelhout & KL Zaglaniczny (eds) Nurse Anesthesia 3rd edition. Pages
977-1030.
Kleinman, W. & Mikhail, M. (2006). Spinal, epidural, & caudal blocks. In
G.E. Morgan et al Clinical Anesthesiology, 4th edition. New York: Lange
Medical Books.
Warren, D.T. & Liu, S.S. (2008). Neuraxial Anesthesia. In D.E. Longnecker
et al (eds) Anesthesiology. New York: McGraw-Hill Medical.